EP4302036A1 - Rotary kiln and method for calcining carbonate-containing material, in particular limestone or dolomite - Google Patents

Abstract

The present invention relates to a rotary kiln for calcining carbonate-containing material, in particular limestone or dolomite, comprising: a rotary tube (1) having an inlet end (2a) for feeding in the material to be calcined and an outlet end (4a) for discharging the calcined material; and a calciner unit (5) which is arranged in the region of the outlet end (4a), the rotary tube (1) having an inlet zone (2) at its inlet end (2a) and having an outlet zone (4) at its outlet end (4a), with a preheating zone (3a) and a calcining zone (3b) being arranged between the inlet zone (2) and the outlet zone (4) in the transport direction of the material. The rotary kiln is characterised according to the invention in that a plurality of projections (7) is arranged in the preheating zone (3a) of the rotary tube (1), the projections (7) being arranged in groups (71) one behind the another and substantially in parallel with the longitudinal axis of the rotary tube (1), with projections (7) of adjacent groups (71) of projections (7) that are adjacent in the circumferential direction of the rotary tube (1) being offset relative to one another in the longitudinal direction of the rotary tube (1) such that spiral transport paths (S) for the material to be calcined are formed in the preheating zone (3a). The present invention further relates to a method for calcining carbonate-containing material, in particular limestone or dolomite.

Description

Rotary kiln and process for burning carbonate-containing material, in particular limestone or dolomite

The invention relates to a rotary kiln for burning material containing carbonate, in particular limestone or dolomite, comprising a rotary kiln with an inlet end for feeding in the material to be burned and an outlet end for discharging the burned material, and a burner unit arranged in the area of the outlet end, with the rotary kiln on has an inlet zone at its inlet end and an outlet zone at its outlet end, a preheating zone and a combustion zone being arranged between the inlet zone and outlet zone in the transport direction of the material. Furthermore, the present invention relates to a method for burning carbonate-containing material, in particular limestone and dolomite, in such a rotary kiln.

Rotary kilns for burning carbonate-containing material have been known from the prior art for decades and have proven themselves as an efficiently and reliably working kiln type for the continuous calcination of various types of materials. Printed prior art can be found, for example, in EP 0 004 756 A2 or US Pat. No. 5,873,714.

The central component of a rotary kiln is a long cylindrical rotary kiln (often 100 m or longer), which is typically inclined at about 2 to 7% to the horizontal. The rotary tube rotates slowly around its axis at 0.5 to 1.5 rpm and the material to be burned, which is introduced into the rotary tube at its inlet end by means of a screw conveyor or similar, moves slowly through the rotary tube in the direction of one by one due to gravity flame generated by burners arranged in the area of the furnace outlet. The material to be burned moves from the inlet zone, which is a few meters long, into the preheating zone (sometimes also referred to as the transition zone), in which temperatures of around 1100 - 1200 °C are already reached are present, and from there into an extensive combustion zone with maximum temperatures of 1500 - 1600°C. Accordingly, the actual calcination of the material to be burned takes place here to a very large extent. The firing zone is followed by the outlet zone of the rotary kiln, which is only a few meters long, from where the fired material usually falls through a shaft onto a cooling unit. The kiln is usually filled with the material to be fired up to about 8 to 20% of the kiln diameter.

Efficient kiln operation always strives for high throughput rates while ensuring that calcination of the material to be fired is complete and that all carbon dioxide is removed from the material.

Thorough mixing of the material to be burned is of decisive importance for rapid and complete calcination.

Another problem in practical operation is the formation of dust. On the one hand, this leads to material loss and, on the other hand, to the release of dust into the environment, which is disadvantageous for ecological reasons and can also pose a health risk depending on the concentration.

It is therefore the object of the present invention to provide a rotary kiln for burning carbonate-containing material, in particular limestone or dolomite, of the type mentioned at the outset, which ensures a high material throughput and the most complete possible calcination of the material to be burned. Furthermore, a significant reduction in dust formation is aimed for in furnace operation.

According to a first aspect of the present invention, the above-mentioned object is achieved with a rotary kiln according to the preamble of claim 1 in that a plurality of projections are arranged in the preheating zone of the rotary kiln, the projections being arranged one behind the other as groups essentially parallel to the longitudinal axis of the rotary kiln are arranged, wherein in the circumferential direction of the rotary tube adjacently arranged projections of adjacent groups of Projections are arranged offset from one another in the longitudinal direction of the rotary tube in such a way that spiral transport paths for the material to be burned are formed in the preheating zone.

The rotary kiln according to the invention is characterized by reliable operation with a high, uniform material throughput. In particular, the provision of a plurality of projections - technically also called "carriers" - which according to the invention are arranged one behind the other as groups essentially parallel to the longitudinal axis of the rotary tube, results in a greatly improved mixing of the material to be burned and thus faster calcination in the same time intervals , since as a result of the thorough mixing not only the superficial material in the material bed is exposed to high calcination temperatures.

The inventively provided staggered arrangement of adjacent projections in the circumferential direction of the rotary tube, the projections each belonging to adjacent groups of projections, spiral-shaped transport paths are formed for the material to be burned. This enables the material to be burned to be transported through the rotary kiln comparatively quickly, which, in combination with the improved mixing of the material, leads to a higher kiln throughput overall and thus increases the efficiency of the combustion process.

Due to the very high temperatures already prevailing in the preheating zone, it is preferred according to a first advantageous embodiment of the invention that at least some of the projections, preferably all of them, each contain a refractory material. This can involve various high-temperature-resistant materials. Concrete, in particular refractory concrete, as is known per se from the prior art, has proven to be particularly suitable. Tests carried out by the applicant have shown that various geometries are suitable for the projections provided according to the invention in the preheating zone. Prismatic geometries are preferred, in particular in the form of a trapezoidal prism, especially an isosceles trapezoidal prism. Such a trapezoidal prism is preferably aligned parallel to the longitudinal extension of the rotary tube and accordingly has two side surfaces inclined to the radius of the rotary tube. These can enclose an angle to the base of the trapezium of between 15° and 85°, preferably between 35° and 75° and particularly preferably between 60° and 70°.

Extensive investigations were carried out by the applicant with regard to the dimensioning of the projections. It has been found that particularly good results in terms of thorough mixing of the material to be burned with little dust formation can be achieved if at least some projections have a height in relation to the rotary tube radial direction between 50 mm and 500 mm, preferably between 100 mm and 300 mm and particularly preferably about 200 mm.

Furthermore, particularly good results in terms of thorough mixing of the material and rapid transport of the material through the preheating zone of the rotary kiln can be achieved in that at least some projections have a length in the longitudinal direction of the rotary kiln of between 50 mm and 2000 mm, especially between 100 mm and 1000 mm. preferably between 200 mm and 750 mm and particularly preferably between 350 mm and 450 mm, typically about 400 mm.

Furthermore, the width of at least some projections perpendicular to the longitudinal direction of the rotary tube can be between 50 mm and 1000 mm, preferably between 100 mm and 500 mm and particularly preferably between 150 mm and 300 mm, typically 300 mm. As already mentioned, trapezoidal geometries in particular have proven to be particularly advantageous for the projections. With regard to the dimensioning of the trapezoidal surface, which is essentially perpendicular to the longitudinal axis of the furnace, it is preferred that the width of the lower trapezoidal base is between 100 mm and 400 mm, preferably between 150 mm and 300 mm, typically around 300 mm, and the width of the upper base is between 30 mm and 200 mm, preferably between 50 mm and 200 mm and particularly preferably between 70 mm and 130 mm, typically about 100 mm.

According to the invention, the projections are arranged one behind the other as groups essentially parallel to the longitudinal axis of the rotary tube. According to the applicant's investigations, it is preferred that the ratio between the length of a projection in the longitudinal direction of the rotary tube and the distance between two adjacent projections in the longitudinal direction of the rotary tube is between approximately 2:1 and 1:2, preferably between approximately 1.5 :1 and 1:1.5, and most preferably is about 1:1. On the one hand, this ensures thorough mixing of the material, and on the other hand, the distances are dimensioned in such a way that sufficiently wide spiral-shaped transport paths result between the projections.

The projections provided according to the invention in the combustion zone can be permanently connected to the inner lining of the rotary tube. However, to ensure a secure connection between the inner lining of the rotary tube and the projections, a further advantageous embodiment of the invention provides that at least some of the projections are attached to the inside of the rotary tube casing by means of a welded metal anchor.

According to a further advantageous embodiment of the invention, it is provided that 3 to 9, especially 4 to 8, particularly preferably 5 to 7, and very particularly preferably 6 groups of projections arranged one behind the other in the longitudinal direction are distributed over the circumference of the rotary tube. The groups provided according to the invention of projections arranged one behind the other essentially parallel to the longitudinal axis of the rotary tube can be arranged along the entire length of the preheating zone. According to a particularly advantageous embodiment of the invention, it is provided that the groups of projections extend over one-fifth to one-third of the total length of the rotary tube.

According to a particularly advantageous embodiment of the invention, it can also be provided that at least one further projection, preferably a plurality of further projections, is provided in the inlet zone of the rotary tube, the at least one further projection having at least one sliding surface inclined to the longitudinal axis of the rotary tube for conveying material to be burned from the inlet zone into the preheating zone.

This exploits the fact that the material to be burned comes to rest on the at least one sliding surface of the material bed due to the rotation of the at least one further projection and due to the special inclination of the sliding surface slides quickly in the direction of the preheating zone due to gravity. It goes without saying here that the direction of rotation of the rotary tube and the orientation of the sliding surface in the circumferential direction of the rotary tube must be adapted to one another. At the same time, this also significantly reduces the formation of dust, since the material to be burned is effectively prevented from being ground up on the wearing rings of the kiln inlet seal as a result of a backward movement of the material in the inlet zone.

Different angles of inclination can be provided for the sliding surface of the at least one further projection. According to an advantageous embodiment of the invention, the sliding surface of the at least one further projection has an inclination to the longitudinal axis of the rotary tube of 15° to 70°, in particular of 35° to 55°. Particularly good results were achieved with an angle of inclination of between 40° and 50°, specifically around 45°. Due to the high temperatures already prevailing in the inlet zone of the rotary tube, it is preferred that the at least one further projection contains a refractory material. This can involve various high-temperature-resistant materials, as is known per se from the prior art. Concrete, in particular refractory concrete, as is known from the prior art, has proven to be particularly suitable.

Tests by the applicant have shown that various geometries are suitable for the at least one further projection. Prismatic geometries are preferred, in particular in the form of a right prism with a triangular base, especially in the form of a right-angled triangle, in which the at least one sliding surface is formed by the hypotenuse of the right-angled triangle.

The height of the at least one projection, i.e. the extent in relation to the cylindrical rotary tube in the radial direction, is important for particularly good effectiveness in relation to the conveyance of the material to be burned from the inlet zone in the direction of the preheating zone. According to an advantageous embodiment of the invention, the at least one further projection has a height extending in the radial direction of the rotary tube of 100 mm to 500 mm, preferably 160 mm to 300 mm and particularly preferably 180 mm to 250 mm, typically approx.

200mm, on. This ensures that a sufficient quantity of material rests on the at least one sliding surface of the at least one further projection and subsequently slides in the direction of the preheating zone due to the inclination of the sliding surface. Furthermore, it can be provided that the at least one further projection has a length of 100 mm to 2000 mm, preferably 300 mm to 500 mm and very particularly preferably 350 mm to 450 mm, typically approx. 400 mm, extending essentially parallel to the longitudinal axis of the rotary tube , having.

The at least one further projection can be permanently connected to the inner lining of the rotary tube. However, to ensure a secure connection between the inner lining of the rotary tube and the at least one further projection, it is provided according to a further advantageous embodiment of the invention that the at least one further projection is fastened to the inside of the rotary tube shell by means of a metal anchor, in particular a welded metal anchor.

According to a particularly advantageous embodiment of the invention, it is provided that a plurality of further projections are provided in the inlet zone of the rotary tube, the further projections being arranged in a row as a group in such a way that the respective sliding surfaces of the further projections form a common sliding surface for the material to be burned form. This achieves a particularly effective conveyance of the material to be burned from the inlet zone of the rotary kiln to its preheating zone. The individual further projections can be lined up in abutment, i.e. essentially without a gap. It is also possible to line them up in a row with a gap in between, in order to take account of thermal expansion, for example, but the width of the gap must be dimensioned in such a way that the function of a common sliding surface is retained.

Because a common sliding surface is provided by a plurality of further projections lined up as a group, a particularly long sliding surface can be provided on the one hand, which extends practically along the entire extent of the inlet zone. At the same time, in the event of damage, for example to a single further projection from the group of further projections lined up next to one another, it can be replaced in a targeted manner without having to dismantle the entire construction.

The group of further projections arranged in a row can comprise a different number of further projections. In particular, the common sliding surface for the material to be burned by 3 to 9 further projections, in particular by 5 to 7 further projections and very particularly preferably formed by 6 further projections.

In terms of the simplest possible construction of the rotary kiln according to the invention, it is particularly preferred that the plurality of further projections are designed essentially identical to one another, such that a common sliding surface is formed with an essentially constant gradient or sliding angle to the longitudinal axis of the rotary kiln.

A further improvement in the conveyance of the material to be burned through the inlet zone of the rotary tube is achieved by arranging 2 to 8, in particular 4 to 6 and very particularly preferably 6 further projections or groups of further projections arranged in a row around the circumference of the rotary tube.

According to a further particularly advantageous embodiment of the invention, it can be provided that the rotary tube has at least one additional projection, preferably a group of additional projections, in the area of the outlet zone to prevent cluster formation in the fired product. This results in a particularly uniform cooling of the entire fired material in the area of the outlet end, which effectively improves the kiln output and the quality of the fired material and also protects downstream system components, such as grate coolers, from overheating. This in turn leads to an extended lifespan of the entire furnace.

A plurality of additional projections is preferably provided in the area of the run-out zone, with the additional projections being arranged as groups in the circumferential direction of the rotary tube. The additional projections arranged in groups over the circumference are preferably offset from one another in the longitudinal direction of the rotary tube in order to maximize the mixing of the material and thus the uniformity of the cooling effect. Again, in A plurality of groups of additional projections—for example three—are preferably provided in the longitudinal direction of the rotary tube.

The additional projections can have different geometries. The geometry of a truncated pyramid with the base of an isosceles acute-angled triangle with a preferably truncated tip for stability reasons is particularly preferred, the truncated acute angle leading in the direction of rotation of the rotary tube and thus plowing through the burned material. In order to ensure adequate heat resistance, it can be provided that the additional projections contain concrete, in particular refractory concrete according to the prior art. The additional projections preferably have a height of between 100 mm and 300 mm, preferably approx. 200 mm, and a length in the circumferential direction of the rotary tube (height of the isosceles triangular base surface of the truncated pyramid) of between 300 mm and 500 mm, preferably approx. 400 mm on. The width of the side of the triangle opposite the acute angle of the isosceles triangular base area is between 50 mm and 150 mm, preferably about 300 mm.

According to a further aspect of the present invention, the object mentioned at the outset is achieved with a method for burning carbonate-containing material, in particular limestone or dolomite, which has the following steps:

- Introduction of the carbonate-containing material into the rotary kiln of a rotary kiln according to one of claims 1 to 14,

- firing of the carbonated material, with the carbonated material moving through the rotary tube from the inlet zone through the preheating zone and the firing zone to the outlet zone, with the rotary tube rotating in one direction of rotation,

- Conveyance of the carbonate-containing material through the preheating zone, wherein the groups of projections arranged one behind the other essentially parallel to the longitudinal axis of the rotary tube are arranged offset to one another in the longitudinal direction of the rotary tube and the rotational speed and Inclination of the rotary tube are adjusted in such a way that the material is conveyed through the preheating zone on spiral transport paths.

The advantages mentioned above apply accordingly to the method. In particular, an efficient firing process is proposed, which is characterized by a high material throughput through the rotary kiln, a consistently high product quality in the fired material as a result of complete calcination, and easy implementation. In particular, the groups of projections in the preheating zone ensure that the material to be burned is thoroughly mixed with minimal formation of dust.

The invention is explained in more detail below with reference to a drawing showing an exemplary embodiment. Show it:

1 shows the rotary kiln of a rotary kiln in a perspective view,

FIG. 2 shows the rotary tube of FIG. 1 in an interrupted perspective longitudinal sectional view,

3 shows an enlarged detail of the preheating zone of the rotary tube of FIG. 1 in a perspective longitudinal sectional view,

4 shows a projection of the preheating zone of the rotary tube of FIG. 1 in a perspective view,

5 shows the two-dimensional interrupted representation of the "unfolded" open inner wall of the rotary tube of FIG. 2 in a highly schematic form,

6 shows an enlarged detail of the rotary tube of FIG. 1 with a partially cut-out furnace wall in a perspective view, 7 shows an enlarged detail of the inlet zone of the rotary tube of FIG. 1 in a perspective longitudinal sectional view,

8 shows a further projection in the inlet zone of the rotary tube of FIG. 1 in a perspective view,

9 shows an enlarged section of the outlet zone of the rotary tube of FIG. 1 in a perspective longitudinal sectional view, and

10 shows an additional projection in the outlet zone of the rotary tube of FIG. 1 in a perspective view.

1 shows the rotary kiln 1 of a rotary kiln with the usual bearing and drive components, which are not discussed in any more detail below. The rotary tube 1 comprises an inlet end 2a and a rear outlet end 4a--shown here on the front side. Along the longitudinal extent of the rotary kiln 1, the rotary kiln 1 comprises an inlet zone 2, a preheating zone 3a (also called "transition zone"), a combustion zone 3b and an outlet zone 4 (see also Fig. 2) with regard to the material feed, combustion and material discharge process and 5). In the area of the outlet end 4a, a burner lance 5 is arranged, by means of which a flame is generated during operation of the rotary kiln that protrudes into the rotary kiln 1. If the rotary kiln 1 has a total length of about 90 m, for example, the length of the Inlet zone 2 is typically around 2 m, that of the preheating zone 3a around 32 m, the length of the combustion zone 3b around 53 m and that of the outlet zone 4 around 3 m Burning zone 3b achieved and amount to about 1500 - 1600 ° C, so that the vast majority of the calcination reaction takes place in this zone.

As shown in the perspective longitudinal sectional view of the rotary tube 1 in FIG. 2 , the rotary tube 1 comprises a plurality of projections 7 (also called “carriers”) in the preheating zone 3a. As can be seen, these are in groups 71 arranged parallel to the longitudinal axis of the rotary tube 1 one behind the other. A total of six groups 71 of projections 7 are distributed over the inner circumference of the rotary tube 1, as can be seen in particular from the representation of the "unrolled" open inner wall in FIG 7 adjacent groups 71 of projections 7 are offset from one another in the longitudinal direction of the rotary tube 1 (see FIG. 5).Since, as can be seen in FIGS Projections 7 and the spaces between the projections 7 is identical for each group 71 - accordingly, entire adjacent groups 71 are also offset from one another in the longitudinal direction of the rotary tube 1. The groups 71 of the projections 7 preferably take up one third to one fifth of the total length of the rotary tube 1 claim.

A more detailed representation of the projections 7 is shown in FIG. 3. Here and in FIG. 4 it can first be seen that the projections 7 are each designed as a trapezoidal prism with a length of approximately 400 mm in the present case and a height of approximately 200 mm in the present case. Furthermore, the width of the lower trapezoidal base is approximately 300 mm, while the upper trapezoidal base has a width of approximately 100 mm in the present case. In this way, inclined leg surfaces 7a are defined along the longitudinal extent of the projections 7, here at an angle of approximately 76° to the lower trapezoid base. The trapezoidal design of the projections 7 ensures that the material mixed during furnace operation by the projections 7 in the preheating zone 3a does not fall off the projections 7 with increased formation of dust, but slides down along the side surfaces 7a.

As can be seen from the furnace lining shown in Fig. 4, the length of the gaps between the rows of projections 7 of a group 71 corresponds approximately to the length of the projections 7 themselves and the projections 7 of adjacent groups 71 are thus offset from one another with a "gap". are spiral or snail-shaped transport paths through the preheating zone 3a of the rotary tube 1 (shown as oblique dashed lines S in FIG. 5), on which the material to be burned can be transported quickly through the preheating zone 3a.

2 also shows that a plurality of further projections 6 are arranged in the inlet zone 2 of the rotary tube 1, which have a specific shape and are arranged in a row as groups 61 in a stepped form, as will be described below. The projections 6 are also referred to in technical terms as “displacers”.

As shown in FIGS. 1, 2 and 5-8, the further projections 6 lined up as a group 61 of six in this case are essentially identical to one another and, according to FIG , isosceles triangle with the non-right angles of the triangle truncated. Each further projection 6 has a sliding surface 6a, which is arranged at an angle to the longitudinal axis of the rotary tube 1. An angle of inclination of approximately 45° is preferably chosen. As mentioned, the additional projections 6 are lined up in a stepped manner in such a way that the individual sliding surfaces 6a of the additional projections 6 form a common sliding surface 6a*, which is also at an angle of approx. 45° to the longitudinal axis of the Rotary tube 1 is inclined.

Furthermore, the sliding surfaces 6a of the further projections 6 or the common sliding surface 6a* of the projections 6 lined up in groups are aligned relative to the direction of rotation D of the rotary tube 1 in such a way that during operation of the furnace the material to be burned (not shown) rests on the sliding surfaces 6a of the further projections 6 comes to rest, and due to the selected inclination of the sliding surfaces 6a to the longitudinal axis of the rotary tube 1, due to gravity, slides quickly in the direction of the preheating zone 3 without the material to be burned being undesirably moved backwards in the direction of the inlet end 2a. As shown in FIGS. 1 and 5, a plurality of groups 61 of further projections 6 lined up in a stepped manner are distributed over the circumference on the inner wall of the rotary tube 1 . A number of six groups 61 is selected here.

2 also shows that a plurality of additional projections 8 are provided in the outlet zone 4 of the rotary tube 1, the additional projections 8 being arranged as groups 81 in the circumferential direction of the rotary tube 1 and being offset from one another in the longitudinal direction of the rotary tube 1. These additional projections 8 (technically "swords") serve to avoid cluster formation in the fired material. As shown in Fig. 10, these additional projections 8 have the shape of a truncated pyramid with the base of an isosceles acute-angled triangle, with the acute angle in the direction of rotation D of the rotary tube 1 and is slightly truncated for reasons of stability. The run-out zone 4 with the additional projections 8 is shown again in detail in FIG. to each other and to the groups 71 of the projections 7 ("carriers") in the preheating zone is shown in FIG. 5.

In Fig. 5 is now a representation of the "unfolded" furnace inner wall of the rotary tube 1 is shown in a highly schematic form. This means that the distribution of all provided projections 7 ("entrainment") in the preheating zone 3a, further projections 6 ("displacer") in the inlet zone 2 and additional projections 8 (“blades”) in the outlet zone 4 of the rotary tube 1 in a two-dimensional representation, with the combustion zone 3b, in which no projections are provided here, not being shown in full for reasons of space. Accordingly, in the inlet zone 2, six groups 61 are distributed over the circumference, each with five further projections 6 ("displacers") arranged in a stepped row. In the preheating zone 3 adjoining the inlet zone 2, there are also six groups 71 according to the invention arranged one behind the other in the longitudinal direction of the rotary tube 1 Projections 7 (“carriers”) are provided. In the circumferential direction, adjacent projections 7 are offset from one another, as shown by the auxiliary line V in FIG can move through the preheating zone 3a without obstacles

Transport paths are shown in the two-dimensional representation of FIG. 5 as parallel oblique lines S by way of example.

Also shown in Fig. 5 are the additional projections 8 (“swords”) provided in the run-out zone 4 of the rotary tube 1. As mentioned, these are shown in

Circumferentially arranged in groups 81 of the rotary tube 1, the additional projections 8 of a group 81 being offset from one another in the longitudinal direction in order to process a maximum amount of burned material. The offset in the longitudinal direction of the rotary tube 1 is shown in FIG. 5 by the auxiliary line V'. In the present case, two groups 81 of five additional projections 8 are provided. The group 81 arranged at the outlet end 4 of the rotary tube comprises only three additional projections 8. In contrast to the projections 6 of the inlet zone 2, the additional projections 8 do not reach the outlet end 4a of the rotary tube 1. Rather, a certain distance of preferably about 1 m can be chosen.

Claims

patent claims

1. Rotary kiln for burning carbonate-containing material, in particular limestone or dolomite, comprising a rotary kiln (1) with an inlet end (2a) for feeding in the material to be burned and an outlet end (4a) for discharging the burned material, and one in the area of the Burner unit (5) arranged at the outlet (4a), the rotary tube (1) having an inlet zone (2) at its inlet end (2a) and an outlet zone (4) at its outlet end (4a), with between the inlet zone (2) and outlet zone (4), a preheating zone (3a) and a combustion zone (3b) are arranged in the transport direction of the goods, characterized in that a plurality of projections (7) are arranged in the preheating zone (3a) of the rotary tube (1), the projections (7) as groups (71) are arranged one behind the other essentially parallel to the longitudinal axis of the rotary tube (1), wherein in the circumferential direction of the rotary tube (1) adjacently arranged projections (7) of adjacent groups (71) of projections (7) in län gs direction of the rotary tube (1) are arranged offset to one another, such that in the preheating zone (3a) spiral transport paths (S) are formed for the material to be burned.

2. Rotary kiln according to claim 1, characterized in that the projections each contain a refractory material, the refractory material optionally being concrete, in particular refractory concrete.

3. Rotary kiln according to one of claims 1 or 2, characterized in that at least some projections (7) have a prismatic geometry, in particular the geometry of a trapezoidal prism, preferably an isosceles trapezoidal prism.

4. Rotary kiln according to one of claims 1 to 3, characterized in that at least some projections (7) have a height in relation to the rotary kiln (1) radial direction between 50 mm and 500 mm, preferably between 100 mm and 300 mm and particularly preferred of approx. 200 mm, and/or at least some projections (7) have a length in the longitudinal direction of the rotary tube (1) between 50 mm and 2000 mm, especially between 100 mm and 1000 mm, preferably between 200 mm and 750 mm and especially preferably between 350 mm and 450 mm, and/or that at least some projections (7) have a width perpendicular to the longitudinal direction of the rotary tube (1) between 50 mm and 1000 mm, preferably between 100 mm and 500 mm and particularly preferably between 150 mm and 300 mm.

5. Rotary kiln according to one of claims 3 to 4, characterized in that at least some projections (7) have the geometry of a trapezoidal prism, the width of the lower trapezoidal base being between 100 mm and 400 mm, preferably between 150 mm and 300 mm, and the width of the upper base between 30 mm and 200 mm, preferably between 50 mm and 200 mm and more preferably between 70 mm and 130 mm.

6. Rotary kiln according to one of Claims 1 to 5, characterized in that the ratio between the length of a projection (7) in the longitudinal direction of the rotary duct (1) and the distance between two adjacent projections (7) in the longitudinal direction of the rotary duct (1) is between ca.2:1 and 1:2, preferably between about 1.5:1 and 1:1.5, and most preferably about 1:1.

7. Rotary kiln according to one of claims 1 to 6, characterized in that at least some of the projections (7) are attached to the inner wall of the rotary kiln (1) by means of a metallic anchor, in particular a welded metallic anchor.

8. Rotary kiln according to one of claims 1 to 7, characterized in that distributed over the circumference of the rotary kiln (1) 3 to 9, especially 4 to 8, particularly preferably 5 to 7, and very particularly preferably 6 groups (71) in the longitudinal direction successively arranged projections (7) are provided.

9. Rotary kiln according to one of claims 1 to 8, characterized in that the groups of projections (7) arranged one behind the other essentially parallel to the longitudinal axis of the rotary kiln (1) extend over one fifth to one third of the total length of the rotary kiln (1).

10. Rotary kiln according to one of claims 1 to 9, characterized in that in the inlet zone (2) of the rotary kiln (1) at least one further projection (6), preferably a plurality of further projections (6), is provided, wherein the at least a further projection (6) has at least one sliding surface (6a) inclined to the longitudinal axis of the rotary tube (1) for conveying the material to be burned from the inlet zone (2) into the preheating zone (3a).

11. Rotary kiln according to claim 10, characterized in that in the inlet zone (2) of the rotary kiln (1) a plurality of further Projections (6) are provided, the further projections (6) being arranged in a row as a group (61) such that the respective sliding surfaces (6a) of the further projections form a common sliding surface (6a*) for the material to be burned.

12. Rotary kiln according to claim 11, characterized in that the common sliding surface (6a*) formed by the plurality of further projections (6) extends essentially over the entire length of the inlet zone (2).

13. Rotary kiln according to one of claims 10 to 12, characterized in that the at least one sliding surface (6a) of the at least one further projection (6) has an inclination to the longitudinal axis of the rotary kiln (1) of 15° to 70°, in particular of 25° to 65°, especially from 35° to 55° and particularly preferably from 40° to 50°.

14. Rotary kiln according to one of claims 1 to 13, characterized in that a plurality of additional projections is provided in the area of the outlet zone (4), the additional projections (8) in the circumferential direction of the rotary kiln (1) as groups (81), in the longitudinal direction of the rotary tube (1), preferably offset from one another, wherein a plurality of groups (81) of additional projections (8) are optionally provided in the longitudinal direction of the rotary tube (1).

15. A method for firing carbonate-containing material, in particular limestone or dolomite, characterized by the following steps: - Introduction of the carbonate-containing material into the rotary kiln (1) of a rotary kiln according to one of Claims 1 to 14,

- Firing of the carbonated material, with the carbonated material moving through the rotary tube from the inlet zone (2) through the preheating zone (3a) and the firing zone (3b) to the outlet zone (4), with the

rotary tube rotates in a direction of rotation (D),

- Conveyance of the carbonate-containing material through the combustion zone (3), wherein the groups (71) of projections (7) arranged one behind the other essentially parallel to the longitudinal axis of the rotary kiln (1) are arranged offset to one another in the longitudinal direction of the rotary kiln (1) and the

The rotational speed and inclination of the rotary tube (l) are adapted in such a way that the material is conveyed through the preheating zone (3a) on spiral transport paths (S).